Fluid pressure brake



Nov. 15, 1938. c. A. CAMPBELL lFLUID PRESSURE BRAKE Filed May 10, 1934 3 Shees--Sleeil 1 Clttornegs Mw ES MME kwil , C. A. CAMPBELL FLUID PRESSURE'BRAKE Nov. 15, 1938.

Filed May 1o, 1954 5 Sheets-Sheet 2 nventat Gttornegs 3 Sheets-Sheet 3 Gttornegs Patented Nov. 15, 1938 FLUID PRESSURE BRAKE Charles A. Campbell, Watertown, N. Y., assigner to The New York Air Brake Company, a corporation of New Jersey Application May 10, 1934, Serial No. 724,988

47 Claims.

This invention relates to air brakes, and particularly to straight air brakes of the type using a control line, and a supervisory line, which serves as a reservoir line, in conjunction with 5 relay brake valves responsive to control line pressure and serving to admit and exhaust air to and fromcorresponding brake cylinders. Relay reservoirs fed through check valves by the supervisory line are used as sources for brake cylinder l air.

The invention resides chiey in mechanism associated with such relay brake valves to control their action so as to ensure brake applications if the supervisory line is ruptured, and

15 permit the production of an application When the control line is ruptured.

The invention involves features of patentable novelty in the relay brake Valve mechanism, and also in combinations of such mechanism with a control system intended for high speed trains, and described and claimed in a copending application Serial No. '724,987 led May 10, 1934. Such system is shown here as a basis for claiming system combinations including the improved relay valve.

The essential elements of the system disclosed in said prior application, comprise an engineers brake valve for exercising the primary manual control, an associated deadman valve (a safety 30 feature whose use is optional); a brake application valve, which protects the main reservoir charge in the event of rupture ofthe supervisory line, and in case of rupture or venting of the supervisory line function to initiate a brake ap- 35 plication; (optionally) a manually operable bypass valve for quickly recharging the supervisory line; a deceleration controller for regulating the development of control line pressure in response to the deceleration produced by a brake applica- 40 tion; and, preferably, a master relay valve which serves as an intermediary between the above recited elements and the control line, securing rapid changes of control line pressures by the use of devices, all of which, except the master relay, 45 are characterized by small ports, short valve travel, and consequently small size and weight.

With a system such as that just outlined, the present invention contemplates the use of relay brake valves controlling brake cylinder pressure 50 and involving various structural refinements. Such relay valves are each associated with a corresponding change-over valve, and brake cylinder pressure limiting valve. The changeover valve responds to the condition of charge 55 of the supervisory line and the condition of charge of the control line to produce certain important results. First, it ensures an application of the brakes during charging of the system until a safely charged condition is reached, at which time the application may be released through 5 the engineers brake valve when in release position. Second, it ensures an application of the brakes if the supervisory line is vented by rupture or otherwise and subjects that application to control by the deceleration controller ifA the control line is intact and the associated mechanism operative, and to control by the pressure limiting valve in case control line pressure be not developed in a definite short period, a condition which may be caused by rupture of the control line, or other derangement of the system. The delay period feature of this second function may be omitted if desired.

Rupture of the control line does not automatically produce an application', but leaves the sys- 20 tem in a condition such that an application may be caused by venting the supervisory line. Such venting is conveniently accomplished by permitting the deadmanvalve to act, and applications produced under the condition stated are controlled by the pressure limiting valve.

The importance of limitation of brake cylinder pressure .arises from the high speed at which thev trains are operated and the high deceleration rates which are necessary when such trains are controlled by block signal systems in which the blocks are of` the present lengths. Normally the deceleration is controlled by the deceleration .controller, so as to be as high as possible without danger of sliding wheels. Whenever the deceleration controller is inactive the application must be limited to an intensity such that sliding will not occur at any speed down to the nal stop. This is particularly important with articulated trains, because one at wheel puts an entire train, rather than merely one car, out of use.

A preferred embodiment of the invention is illustrated in the accompanying drawings, in Which,-

Fig. 1 is a View partly in elevation and partly 45 in section, showing the equipment on the leading car (or locomotive).

Fig. 2 is a similar view showing the equipment on two trailing cars.

Fig. 3 is a fragmentary view showing the rotary 50 valve of the engineers brake valve in application position.

Fig. 4 is a sectional view of the service and emergency relay brake valve, including the change-over valve and pressure limiting valve. 56

Fig. 5 is a fragmentary view showing the change-over valve in its shifted position.

Figs. 1 and 2 combined show the system for a three car train. Figs. 1 and 4 are diagrammatic to the extent that the ports are drawn as if they all lay in a single plane, this being a familiar convention in this art to permit various flows to be traced in a single view.

Referring first to Fig. 1, the engineers brake valve comprises a pipe bracket portion 6 to which all pipe connections are made, a seat portion 1 on the lower face of which is the inverted seat for the rotary valve 8, and a bonnet or housing 9 which encloses the deadman handle mechanism.

The main reservoir appears at II and the main reservoir pipe and all branches thereof in free communication therewith are indicated by the numeral I2.

Similarly the supervisory line with its freely communicating branches are indicated by the numeral I3 and the control line and freely cornmunicating branches by the numeral I4.

The bracket 6 is connected to the main reservoir pipe I2, which supplies main reservoir air to the chamber in which the rotary valve 8 is mounted. Supervisory line I3 is connected to bracket 6 and thence to a port I5 in the seat of rotary valve 8. Also in the seat for rotary valve 8 are an atmospheric exhaust port I6, and a port I1, which may be called the control port because it is the port which normally exercises control on the control pipe, through the brake application valve, deceleration controller, and master relay. A pipe I8 connected to bracket 6 communicates with the control port I1.

In release position, shown in Fig. l, a port I9 through the rotary valve 8, admits main reservoir air to supervisory line port I5 and a cavity 2I connects control port I1 with exhaust port I6.

In lap position ports I5, I6 and I1 are blanked. In service position a through port 22 (see Fig. 3) admits main reservoir air to control port I 1, ports I5 and I5 being blanked.

The valve 8 is turned by head 23 on stem 24 which is fast in hub 25. The hub is engaged by the impositive detent which denes the valve positions. Swiveled in hub 25 and urged upward by compression spring 21 is a forked yoke 28. The deadman handle 29 is inserted between the branches of yoke 2B and its inner end engages under lug 3I and between spaced lugs 32 all carried by hub 25, thus locking yoke 28 and hub 25 together, and permitting the handle to operate the valve. The handle must be held down against the urge of spring 21, else it will unseat the poppet vent valve 33 and Vent line 34.

The .deadman valve above described involves patentably novel features, but as these are inventions independent of the control system here under discussion, they are not claimed in the present application.

The vent line 34 is connected to the body 35 of an emergency exhaust valve connected to vent the supervisory line I3 if valve 33 be unseated. In body 35 is a seat 36 controlling an atmospheric port and a combined piston and valve 31 which coacts with seat 36 and is loosely fitted in bushing 38. A Spring 39 urges piston-valve 31 in a closing direction. If valve 33 be closed pipe 34 becomes charged by leakage past the piston during charging of pipe I3 and spring 39 holds the valve closed. Opening of valve 33 vents pipe 34 so that valve 31 opens and vents pipe I 3. The consequent venting of the supervisory line causes a brake application, as will be explained.

The brake application valve is carried in a ported bracket 4I, to which all pipe connections are made, and comprises a body 42, front cap 43 and plug 44 as the enclosing structure. The body encloses a slide valve chamber 45 with which the reservoir line I2 directly communicates through a port 46. In chamber 45 is a seat for slide valve 50. Communicating with chamber 45 is a cylinder which receives piston 41. The piston 41 has a stern with spaced shoulders which embrace slide valve 5I) and cause it to partake of the movements of the piston. A spider 49 guides the piston stem. A coil compression spring 5I reacts between the front cap and the piston, forcing this inward (downward) to a normal position defined by stand-off lugs 52 on the inner side of the piston.

In the normal position so dened, a charging bypass around the piston from chamber 45 to the space within the front cap is aiorded through choke ttings 53, interchangeable to permit adjustment of flow capacity. The space within the front cap is connected by way of port 54 with supervisory line I3. Thus under normal conditions line I3 is charged through choke 53 from the main reservoir. This charging connection is cut off, when piston 48 moves outward and seats against the front cap gasket.

A port 55 in the seat of slide valve 58 is indicated by legends to be connected with accessory apparatus such as a sander and an engine governor for the car propelling engine. In normal position of the slide valve port 55 is vented to atmosphere by way of cavity 56 and exhaust port 51, but in the outer position of the slide valve 5U a through port 58 admits main reservoir air to port 55 to operate the sander and change the loading of the engine governor.

Pipe I8 which communicates with control port I1 of the engineers brake valve leads to a port 6I in the seat of slide valve 58. A pipe 62 leads from two ports 63 and 64 in the seat of slide valve 50. A choke 65 is interposed in port 64. When the slide valve 59 is in the normal position a cavity 66 connects ports 6I and 63 and port 64 is blanked. When the piston moves outward, ports 6I and 63 are disconnected and port 64 is exposed so that main reservoir air flows to pipe 62 at a rate controlled by the size of choke 65.

The pipe 62 leads to the device which responds to deceleration. This comprises a balanced piston valve 61 working in a valve chamber having a port 68 to which pipe 62 is connected, an atmospheric exhaust port 69 and between the two a port 1I connected by pipe 12 with control reservoir 13.

The direction of motion of the train (here assumed to be a single end unit) is indicated by the arrow on Fig. l, and guided on rollers 14, to move in a line parallel to such motion, is an inertia mass 15 whose normal (rear) position is dened by stop 16. Mass 15 reacts through lever 11, fulcrumed at 18, upon the valve 61 in opposition to an initially stressed coil compression spring 'I9 at the rear end of the valve.

No means for adjusting the stress on spring 19 is illustrated, but nothing in the present invention would preclude the use of adjusting means known in the art, some of which are covered by copending applications of the present applicant.

Deceleration of the train at rates produced by application of the brakes causes mass 15 to move forward shifting valve 61. The ports 68 and 69 are so spaced relatively to the reduced middle portion of valve`61, that as the valve is shifted from the normal position in which it connects ports 68 and 1| and blanks port 69, it rst assumes a position in which it blanks ports 68 and 69, and then on slight further motion, assumes a position in which it connects ports 69 and 1| and blanks port 68. The action of the valve obviously is progressive or graduating, and the lap in ports 68 and 69 is slight, so that the action of the valve is quite rened. i

A bypass check valve 18 permits release of the brakes by the engineers brake valve when valve 61 blanks port 68.

Details of the structure of the deceleration controller involve independent inventions and hence are not claimed in the present application. 1

Between control reservoir 13 and control pipe I4 a master relay valve of large ow capacity is interposed. A by-pass check valve I 88, loaded to open when pressure in the control reservoir 13 is eight pounds per square inch or more above pressure in control line I4, assures an application should the master relay valve be sluggish in action, and also permits an application to be made if the main reservoir supply line to the master relay be ruptured.

A bracket 8| supports the relay valve body 82 and to it are connected the supervisory line I2, the control line I4, and pipe 83 leading from control reservoir 13. The body 82 has a plug closure 84 at its lower end and a cap 85 at its upper end, and encloses a slide valve chamber 86 and a cylinder in which Works the relay piston 81. The chamber 86 is in free communication with control pipe I4 by way of port 83, and with the space below piston 81 by restricted port 89, the stem of the piston being enlarged adjacent the piston to lit chamber 86 freely and thus exercise a moderate damping effect on the pistons movements.

The piston actuates an exhaust slide valve 9| of the grid type controlling simultaneously two exhaust ports 92 leading from chamber 86 to atmosphere. The ports 92 are wide open when piston 81 is in its outer (upper) position. As the piston moves inward (downward) valve 9| first closes ports 92, after which the stem engages poppet inlet valve 93 and unseats it against the urge of compression spring 94. This admits main reservoir air by way of main reservoir pipe I2, port 95 and chamber 96 to chamber 86, which, as stated, is connected with the control pipe I4.

A conductors valve 98 is used on each trailer, or wherever desirable, and when manually opened vents the supervisory line I3 to which it is connected.

To accelerate complete venting, whenever initiated by a conductors valve 98 or emergency exhaust valve 35, or any other means, a large capacity vent valve, whose body is indicated at 99, is connected to supervisory line I3. Vent valve 99 is located as close to the brake application valve as is practicable, so that its opening will cause piston 41 to respond despite any feeding flow through choke fitting 53. The body 99 is made in two parts between which is clamped a flexible diaphragm IUI. The diaphragm actuates a pin valve |82 coacting with seat |83 to `control an atmospheric vent port leading from the supervisory line. The diaphragm is urged in a valve closing direction by supervisory line pressure and by a coil compression spring |84. It is subject in the opposite direction to pressure in a chamber |85, charged from the supervisory line through a restricted opening |06. Slow reductions of supervisory line pressure do not affect the diaphragm sufficiently to open the vent valve because of back flow through port |86, but a sudden reduction will cause the vent valve to open wide.

Similar vent valves, permissibly of smaller venting capacity, may be located on the trailers as indicated at |81 and serve to propagate, throughout the length of the supervisory line, an emergency reduction of supervisory line pressure.

To expedite release after an application caused by venting of the supervisory line, a so-called by-pass valve is provided to charge the supervisory line from the main reservoir.

It is preferably located close to piston 41 of the brake application valve and hence is shown mounted on bracket 4I. The by-pass valve is made up of a body |88 bolted to bracket 4I and a cap |89 bolted to body |88. Between the cap and body a iiexible diaphragm III is clamped and serves as a valve in conjunction with the annular seat rib I I2 in body |88. When the diaphragm seats on rib II2 it isolates from each other a central chamber II3 connected through a branch of port 54 with the supervisory line, and a surrounding annular chamber I|4 connected by a branch of port 46 with main reservoir pipe I2. The chamber II Within cap |89 and above diaphragm I II is charged from chamber H4 through choke IIS. An atmospheric vent valve II1 is urged closed by pressure in chamber I I5 and also by a coil compression spring H8 which reacts between the valve and a thrust plate I I9 resting upon diaphragm III. A push button IZI is provided to permit manual unseating of valve II1.

By striking button I2I the operator opens vent valve II1, venting chamber I I5 at a rate greatly in excess of the charging iiow through choke II6. Diaphragm III lifts, connecting chambers II 3 and II4. Piston 41 then shifts .and having shifted the resulting feed through choke 53 maintains suilicient pressure above the piston to hold it down.

The mechanism so far described is disclosed and claimed in said prior application. The relay brake valves now about to be described involve patentable novelty individually and also in combination with such mechanism.

On each vehicle or car there is at least one braking unit. Such units being identical, a description of one will suffice for al1.

A ported pipe bracket |25 is provided and to this all pipe connections are made. The control line port |26 is connected to the control line I4. The supervisory line port |21 is connected to the supervisory line I3 and has a branch leading through a choke |28 to a timing chamber |29. A relay reservoir port I3I is connected by pipe i |32 to relay reservoir |33. A brake cylinder port |34 is connected by pipe |35 to brake cylinder |36. There is also a timing chamber port |31 leading from the timing chamber I 29. Under some conditions it is desir-able toomit choke |28 and timing chamber |29 and in such case port |31 is connected directly with port |21.

Bolted to bracket |25 is a body |38 which houses the relay and the change-over valve mechanisms. The ports |26, |21, I3I, |34 and |31 have similarly numbered extensions in body |38.

One portion of the body |38 is formed with two aligned chambers |39 to which a branch of port 75 |3| leads and |4| which is freely vented to atmo'sphere at |42. The two chambers are separated by an annular partition |43. A branch of brake cylinder port |34 leads to the space within or opening through partition |43.

Sealed against the lower face of partition |43 by means of a gasket and within chamber |39 is a cylinder bushing |44 having ports |45 and |46 near its opposite ends. The bushing is held in place by a removable cover plate |41 which closes the end of chamber |39. Slidable in bushing |44 is a piston-like poppet valve |48 urged upward by a coil compression spring |49 into sealing engagement with a seat rib |5| at the upper end of bushing |44. A gasket on the end of the valve coacts with the seat.

Mounted in the piston valve |48 and controlling a through port in the end thereof is a pilot valve |52 of the poppet type seated by a coil compression spring |53 lighter than spring |49. Valve |52 also carries a gasket to coact with its seat and its pilot has an extension |54 which extends beyond the upper end of valve |48 to ensure serial opening of valves |52 and |48 in the order stated. The valves |52 and |48 control iiow of relay reservoir air from chamber |39 to port |34 and thence to the connected brake cylinder |36. Valve |52 acts as a pilot valve providing for service flow and relieving the seating pressure on valve |48 so that this valve opens without undue resistance if the actuating device moves far enough to unseat it. This occurs in emergency applications, and at such times the lower end of valve |44 blanks port |46.

Mounted in, and spaced from the walls of chamber |4| is a bushing |55, sealed to the body |38 at both ends by gaskets |56. The bushing is held under sealing pressure by a removable cap |51. This bushing forms a slide valve chamber |58 and cylinder |59. In the slide valve chamber is a seat for an exhaust slide valve |6|, the valve |6| controlling an exhaust port |62 in the seat. The slide valve is held to its seat by springs, as shown, and is confined, with slight lost motion, between collars on the stem |63 of an actuating piston |64 which works in cylinder |59. The end of stem |63 engages extension |54 of pilot valve |52 after valve |6| has closed exhaust port |62 and the lost motion between the stem and slide valve |6| is such as to permit graduation of supply flow, by opening and closing pilot valve |52 while the slide valve |6| remains at rest in closed position.

Between piston |64 and stem |63 is a central hub or enlargement |65 which makes a free t in the upper end of slide valve chamber |58. A narrow slot |66 in the periphery of hub |65 offers restricted communication between the space below piston |64 and slide valve chamber |58. This protects the piston from most of the blast effect of air admitted by valves |48 and |52, while subjecting the lower side of the piston to brake cylinder pressure.

To protect the charge in relay reservoir |33 in case the supervisory line |3 is vented, a charging check valve is used. This may be variously located, but it is desirable to interpose it between ports |21 and |3|. A convenient location is in cap |51 and accordingly a charging check |61 with sealing spring |68 and removable cover cap |69 is shown controlling communication between extensions of ports |21 and |3| in cap |51.

Formed in the body |38 is a change-over valve chamber |1| provided with a slide valve chamber bushing |12 with ported seat for change-over slide valve |13. The upper end of the chamber |1| is closed by a flexible diaphragm |14 and the lower end is closed by a exible diaphragm |15, the effective area of diaphragm |14 being approximately twice that of diaphragm |15. Diaphragm 14 is clamped in place at its periphery by cap |16 which is Vented to atmosphere at |11 so that the outer face of the diaphragm is subject to atmospheric pressure. Diaphragm |15 is clamped at its periphery by cap |18 and chamber |19 within the cap is subject to control line pressure admitted by a branch of port |26.

The diaphragms are connected together by a stem |8| which carries clamping disks as shown, the disks embracing the middle portions of the two diaphragms and being retained by nuts threaded on stem l8| as clearly shown. Stem |8| has spaced coll-ars |82 which embrace the slide valve |13 so that the valve partakes of the longitudinal movements of stem |8|. The upper or normal position of the stem |8| (and consequently of valve |13) is deiined by a stop pin |83 fixed in cap |16. Two coil compression springs |34 and |85 react between cap |16 and the upper diaphragm-clamping disk and urge stern |8| downward.

A cap |86 clamps a flexible diaphragm |81 at its periphery and encloses a chamber |88 to which a branch of relay reservoir port |3| leads. A thrust pin |89 with bearer disk |9| transfers the inward thrust of diaphragm |81 to a socketed thrust block |92 on the back of slide valve |13. In this way valve |13 is held seated at all times. The parts are so arranged that pin |89 is at 90 to the seat of Valve |13 when the valve is in midposition.

The seat for valve |13 has three ports; port |93 to which control passage |26 leads, a port |94 connected by passage |95 with the space above relay piston |64, and a port |96 connected by passage |91 with chamber |98 in body |99 of the pressure limiting valve.

The lower wall of chamber |98 comprises a flexible diaphragm 29|, clamped at its periphery by cap 202, which is vented to atmosphere at 203. A check valve 204, with seating spring 265, retained by cap 206, controls flow from a branch of the relay reservoir passage |3| to chamber |98 and closes in the direction of flow toward said chamber. Clamped to the center of diaphragm 20| by a disk and nut, as shown, is a stem 201 which on upward motion of the diaphragm unseats valve 204. A coil compression spring 208 reacts between cap 202 and the diaphragmclamping disk to urge stem 201 and diaphragm 20| upward.

The strengths of springs 295 and 208 are so related to the area of diaphragm 20| that valve 204 will close when pressure in chamber |98 reaches a safe upper limit. The valve determines the limiting pressure exerted on the upper side of piston |64 at times when the deceleration controlling device is ineffective, and the limiting pressure is so chosen that the resulting brake application will be insufficient to lock the wheels at any train speed. In a practical commercial embodiment of the invention the limiting pressure was 60 pounds gage, and that value may be chosen for purposes of discussion.

The slide valve |13 is ported as indicated at 209, the port 209 having three branches so arranged that when valve |13 is in its normal (upper) position control port |98 is connected to relay cylinder port |94 and limiting valve port |96 is blanked. In the lower, or change-over position of valve I13,control port |93 is blanked and limiting valve port |96 is connected with relay cylinder port |94 (see Fig. 5).

The relationship of the engineers brake Valve and the deceleration controller to each other and to the supervisory line, either with or without the master relay and control reservoir, forms the subject matter of my prior application above identied, and hence are not broadly claimed herein. These parts, however, and particularly the brake application valve and deceleration controller enter into special coactive relation with the service and emergency relay valves, such coaction being dependent on the response of the changeover portion and being affected, under certain conditions, by the response of the pressure limiting valve.

When the train is running and the brakes are released, the control line I4 is at atmospheric pressure, the engineers brake valve, brake application valve, deceleration controller, and master relay Valve, are in the positions shown in Fig. l. The parts of the service and emergency relay valve are in the positions shown in Fig. 4. The engineer may make a brake application by shifting the engineers brake Valve to application position (see Fig. 3) in which port 22 admits main reservoir air to port I1, and thence via control pipe I8, through. port 6|, cavity 66, port 63 and pipe 62 to port 68 of the deceleration controller valve. In the normal position of the deceleration controller, port 68 is connected to port 1| and thence via pipe 12 to control reservoir 13. Consequently, under normal conditions the engineers brake valve establishes a brake applying pressure in the control reservoir 13 and this pressure operates upon the master relay valve to establish a corresponding pressure in the control pipe I4. With the change-over portion in normal position of Fig. 4, control pipe |4 is connected to the chamber above pistons |64 of the service andemergency relay valves and these function to establish, corresponding pressures in the brake cylinders by feeding air from the relay reservoirs to the brake cylinders. The relay reservoirs are automatically replenished from the supervisory line through the reservoir charging checks |61.

As soon as application of the brakes produces a deceleration rate sufficient to cause the Weight 15 of the deceleration controller to overpower the spring 19, the deceleration controller valve takes control, blanking the port 68 and establishing a graduated connection between the control reservoir port 1I and the exhaust port 69. Since the intensity of the brake application must be progressively reduced to maintain a uniform deceleration rate, the deceleration controller `takes immediate control of the application, graduating the brakes off to maintain a uniform deceleration rate until the train comes to rest, at which time the deceleration controller resumes its normal position and reconnects ports 68 and 1|, blanking port 69.

If the supervisory pipe is vented in any way, the piston 41 moves upward against resistance of the spring and disconnects the main reservoir from the supervisory line by cutting off the feeding connection through the choke 53. At the same time port 63 is blanked and main reservoir air is admitted through port 64 and choke 65 to the pipe 62, and consequently to the deceleration controller. The effect is to produce an application in the manner already described. As an incidental function the sander port is disconnected from exhaust 51 and subjected. to main reservoir pressureadmitted through the port 58. Main reservoir air thus operates the Sanders and also flows to the engine governor of the train to perform certain regulatory functions, whose details are not involved in the present invention.

The supervisory line might be vented in various ways, such as rupture of the line, operation of a conductors Valve 98, with attendant operation of the emergency vent valves. Also it might be operated by the deadman action incident to release of the handle 29. This unseats the deadman valve 33 and by venting pipe 34 causes emergency exhaust valve in body 35 to vent the supervisory line to atmosphere.

The functions of the service and emergency relay valve in case of the venting of the supervisory line I3, can now be traced.

Referring to Fig. 4, if the line I3 be Vented the charging check valves |61 will close and protect the charges in the relay reservoir I 33. The chamber |29 will start discharging through the choke |28 so that the chamber |19 will start to bleed back to the vented supervisory line. The venting of the supervisory line will cause the brake application valve to function, as already described, and establish a brake applying pressure in the control line |4.

The function of the delay chamber |29 and choke |28 is to delay the depletion of pressure in the chamber I 1| and consequently to delay the descent of stem I8 I under the urge of the springs |84 and |85 long enough to permit pressure in the chamber 19 to build up. Consequently, if the master relay valve functions, as normally it will, and if the control line I4 is intact, pressure will build up in the chamber |19 before pressure in the chamber |1| is depleted, and the changeover` valve 13 will remain in the normal position shown in Fig. 4. Consequently, the control line remains connected to the spaces above pistons |64 of the relay valves and the brake application will be subjected to control by the deceleration controller acting through the control reservoir, the master relay and the control line.

But suppose that the master relay fails to function or that the control line I4 is ruptured. In either event pressure will not be established in the chamber |19 and after the delay interval, imposed by the venting of the delay chamber |29 through choke |28, the springs |84 and |85 will force stem |8| downward, shifting the changev over valve |13 to the position shown in Fig. 5. In this position the control line port |13 is blanked and the change-over port |96 is connected to port |94 and thence to the spaces above the pistons |64 of the service and emergency relay valves. The pressure limiting valve 204 being normally open, air from the relay reservoir will flow from chamber |39 past valve 204 through passage |91 and port |96, cavity 2|I, port |94 and passage |95 to piston |64, and thus establish the brake applying pressure on the relay valve piston. This pressure, however, is limited in amount because when it reaches the chosen value, here assumed to be 60 pounds, the diaphragm 20| will move down against the resistance of spring 208 and close the valve 204. In this way the intensity of the brake application is limited to the value determined by the setting of the pressure limiting valve 204, here assumed to be sixty pounds. This limitation of pressure is necessary because the deceleration controller cannot control as the result of the interruption of its connection through the master relay and the Control line. The pressure limiting valve thus holds the application to an intensity which will prevent locking of the wheels by the brakes.

From the above it follows that the venting of the supervisory line alone will automatically produce an application and this application will be controlled by the deceleration controller if the control line and master relay perform their normal functions. If, however, the control line is ruptured, or the master relay should fail to function, there will still be an application but that application will be limited to a maximum intensity which is maintained throughout the stop without danger of sliding the wheels. If the control line alone be ruptured, an application Will not be automatically produced, but it can be produced. at any time by venting the supervisory line. A convenient Way of performing this function is to release the handle 20 and vent the supervisory line through the operation of the deadman mechanism. An application so produced is limited to sixty pounds by the pressure limiting valve.

It has been suggested that the delay chamber |29 and choke |28 can be omitted, in which case the ports |21 and |31 are in free communication with each other. In such case rupture of the supervisory line |3 will immediately vent the chamber |1|, causing immedate descent of the stem |8| and immediate shifting of the valve |13. It is desirable so to relate the area of the diaphragm |15 to the aggregate strength of the springs |84 and |85 that when chamber |1| is at atmospheric pressure the valve |13 will be shifted to its upper position and to its lower position, respectively, as pressure in the chamber |19 rises above and falls below the setting of the pressure limiting valve 204, here assumed to be 60 pounds. This is particularly important when the delay chamber |29 and choke |28 are omitted.

If the supervisory line I3, and consequently the chamber |1|, are vented when control line |4, and consequently the chamber |19, are at atmospheric pressure, the valve |13 will shift to its lower position, causing the pressure limiting valve 204 to establish a definite pressure (assumed to be 60 pounds) on the piston |64. This would produce a 60 pound brake application which will continue indenitely unless control line pressure rises above 60 pounds.

If the control line is intact, and if the master relay functions, venting of the supervisory line I3 will cause the brake application valve to shift and admit main reservoir air to the control line through the deceleration controller. As a result of this, control line pressure and the pressure in chamber |19 will quickly rise to a value higher than the setting of the pressure limiting valve (60 pounds), and as the pressure in chamber |19 passes above 60 pounds, the valve |13 will shift and connect the control line to the space above piston |64. Consequently brake cylinder pressure rises until the desired deceleration rate is established, whereupon the deceleration controller starts to reduce control line pressure, and consequently brake cylinder pressure, to maintain a uniform deceleration rate as the train slows up. The action of the deceleration controller reduces the pressure in chamber |19 in consonance with the reduction in brake cylinder pressure and when the sixty pound value is reached, the valve 13 again shifts to the position of Fig. 5 and a sixty pound brake cylinder pressure is maintained under the control of the pressure limiting valve. Since the valve |13 shifts at or substantially at the controlling pressure established by the pressure limiting valve, the transition of control from the pressure limiting valve to the deceleration controller and then back to the pressure limiting valve, occurs smoothly and without abrupt changes of brake cylinder pressure.

It should be observed that this action takes place when the supervisory line is completely vented, and will also take place if the supervisory line pressure is depleted sufficiently to cause the change-over Valve to shift. Consequently, protection is had, not merely against rupture of the supervisory line, but also against failure of the compressor or the compressor governor such as would reduce supervisory line pressure below a safe value. Whenever pressure in the supervisory line is maintained the stem |8| and consequently the valve |13, are maintained in their upper normal position of Fig. 4 throughout the stop.

The change-over portion and the pressure limiting valve also exercise an important control during charging of the system for they prevent the engineer from moving his train until the system is adequately charged. At the commencement of charging the springs |84, |85 will hold the stem I8 in its lower position so that valve |13 is in the position of Fig. 5. Air will flow to the relay reservoir |33 and this pressure flowing from chamber |39 through the pressure limiting Valve 204 and slide valve |13, Will establish a brake applying pressure on the piston |64. This will produce a brake application Whose intensity increases as the degree of charge increases. This condition Will continue even though th-e engineers brake valve be in brake-releasing position, until the system is charged to a point at which the supervisory line, and consequently` the chamber I1 I, are charged to a degree at which the pressure in chamber |1|, through its action on the differential diaphragm |14, |15, overpowers the springs |84 and |85. When and only when this condition is attained, the valve 13 will be shifted 4to the normal position of Fig. 4, opening the control line port |93, and placing the engineers brake valve in control of the system. This insures that if the system is partially charged below a certain critical value, the brake application will continue irrespective of the engineers brake Valve. Thus the engineer can not release his brakes under conditions of partial charge of the system unless this charge exceeds a safe minimum value.

It is obvious that this last-named action takes place irrespective of the presence or absence of the delay chamber |29 and choke |28.

l. In a fluid pressure brake system, the combination of a normally charged supervisory line; a local reservoir charged therefrom; means preventing back flow from the reservoir to the supervisory line; a normally vented control line; means for supplying pressure fluid to the control line to develop pressure therein; a brake cylinder; a relay valve comprising an actuating abutment normally subject to control line pressure and valve means operable thereby to admit pressure fluid from said reservoir to the brake cylinder and to exhaust said brake cylinder to control the application of the brakes; means responsive to the depletion of supervisory line pressure for interrupting the communication between said control line and the abutment of said relay valve and for subjecting said abutment to pressure fluid; and means responsive to the rate of deceleration produced by a brake application for cutting oif the supply of pressure fluid to the control line and for thereafter venting pressure fluid therefrom to limit the deceleration rate.

2. In a fluid pressure brake system, the combination of a normally charged supervisory line; a local reservoir charged therefrom; means preventing back flow from the r-eservoir to the supervisory line; a normally vented control line; a brake cylinder; a relay valve comprising an actuating abutment normally subject to control line pressure and Valve means operable thereby to admit pressure iiuid from said reservoir to the brake cylind-er and to exhaust said brake cylinder to control the application of the brakes; valve means responsive to the depletion of supervisory line pressure for interrupting the communication between said control line and the abutment of said relay valve and for subjecting said abutment to pressure iluid; and means responsive to control line pressure and serving above a definite control line pressure to restore the last-named valve means and reestablish communication between the control line and abutment irrespective of the depletion of supervisory line pressure.

3. In a fluid pressure brake system, the combination of a normally charged supervisory line; a local reservoir charged therefrom; means pref' venting back now from the reservoir to the supervisory line; a normally vented control line; a brake cylinder; a relay valve comprising an actuating abutment normally subject to control line pressure and valve means operable thereby to admit pressure uid from said reservoir to the brake cylinder and to exhaust said brake cylinder to control the application of the brakes; valve means responsive to the depletion of supervisory line pressure for interrupting the communication between said control line and the abutment of said relay valve and for subjecting said abutment to pressure iluid; means responsive to control line pressure and serving above a deinite control line pressure to restore the last-named valve means and reestablish communication between the control line and abutment irrespective of the depletion of supervisory line pressure; and means responsive to the rate of deceleration produced by a brake application for modulating the pressure in the control line.

fl. In a fluid pressure brake system, the combination of a normally charged supervisory line; a local reservoir charged therefrom; means preventing back ow from the reservoir to the supervisory line; a normally vented control line; a brake cylinder; a relay valve comp-rising an actuating abutment normally subject to control line pressure and valve means operable thereby tol admit pressure `fluid from said reservoir to the brake cylinder and to exhaust said brake cylinder to control the application of the brakes; means responsive to the depletion of supervisory line pressure for interrupting the communication bctween said control line and the abutment of said relay valve and for subjecting said abutment to pressure uid; means responsive to the depletion of supervisory line pressure for establishing pressure in the control line; and means responsive to control line pressure and serving abo-ve a definite control line pressure to restore communication between the control line and said abutment.

5. In a uid pressure brake system, the combination of a normally charged supervisory line; a local reservoir charged therefrom; means preventing back flow from the reservoir to the supervisory line; a normally vented control line; a brake cylinder; a relay valve comprising an ac tuating abutment normally subject to control line Y pressure and valve means operable thereby to admit pressure fluid from said reservoir to the brake cylinder and to exhaust said brake cylinder to control the application of the brakes; means ron sponsive to the depletion of supervisory line pressure for interrupting communication between said control line and the abutment of said relay valve and for subjecting said abutment to pressure fluid; means responsive to the depletion of supervisory line pressure for establishing pressure in the control line; means responsive to control line pressure and serving above a definite control line pressure to restore communication between the control line and said abutment; and means responsive to the rate of deceleration produced by a brake application for modulating the pressure in the control line.

6. -In a fluid pressure brake system, the combination of a normally charged supervisory line; a local reservoir charged therefrom; means preventing back ilow from the reservoir to the supervisory line; a normally vented control line; a brake cylinder; a relay valve comprising an actuating abutment normally subject to control line pressure and valve means operable thereby to admit pressure uid from said reservoir to the brake cylinder and to exhaust said brake cylinder to control the application of the brakes; means responsive to the depletion of supervisory line pressure for interrupting communication between said control line and the abutment of said relay Valve and for subjecting said abutment to pressure uid; pressure limiting means for limiting the pressure thus developed upon the abutment oi the relay; means responsive to depletion of supervisory line pressure for developing a pressure in the control line; and means responsive to the establishment `of a deiinite pressure in the control line for restoring communication between the control line and the relay abutment.

'7. In a fluid pressure brake system, the combination of a normally charged supervisory line; a local reservoir charged therefrom; means preventing back flow from the reservoir toI the supervisory line; a normally vented control line; a brake cylinder; a relay valve comprising an actuating abutment normally subject to control line pressure and valve means operable thereby to admit pressure fluid from said reservoir to. the brake cylinder and to exhaust said brake cylinder to control the application of the brakes; means responsive to the depletion of supervisory line pressure for interrupting communication between said control line and the abutment of said relay valve and for subjecting said abutment to pressure fluid; pressure limiting means for limiting the pressure so developed upon the abutment of the relay; means responsive to depletion of supervisory line pressure for developing a pressure in the control line; means responsive to the rate of deceleration produced by a brake application for modulating the pressure in the control line; and means responsive to the establishment or" a denite pressure in the control line for restoring communication between the control line and the relay abutment,

8. In a fluid pressure brake system, the combination of a normally charged supervisory line; a local reservoir charged therefrom; means preventing back flow from the reservoir to the supervisory line; a normally vented control line; a brake cylinder; a relay valve comprising an ac-A tuating abutment normally subject to control line pressure and valve means operable thereby to admit pressure iluid from said reservoir to the brake cylinder and to exhaust said brake cylinder to control the application of the brakes; means responsive tothe depletion of supervisory line pressure for interrupting the communication between said control line and the abutment of said relay valve and for subjecting said abutment to pressure fluid; pressure limiting means for limiting the pressure so developed upon the abutment of the relay; means responsive to depletion of supervisory line pressure for developing a pressure in the control line; manually operable means for developing a pressure in the control line; means responsive to the rate of deceleration produced by brake application for modulating pressure in the control line; and means responsive to the establishment of a deilnite pressure in the control line for restoring communication between the control line and the relay abutment.

9. In a fluid pressure brake system, the combination of a normally charged supervisory line; a local reservoir charged therefrom; means preventing back flow from the reservoir to the supervisory line; a normally vented control line; a brake cylinder; a relay valve comprising an actuating abutment normally subject to control line pressure and valve means operable thereby to admit pressure fluid from said reservoir to the brake cylinder and to exhaust said brake cylinder to control the application of the brakes; means responsive to the depletion of supervisory line pressure for interrupting the communication between said control line and the abutment of said relay valve and for subjecting said abutment to pressure fluid; pressure limiting means for limiting the pressure so developed upon the abutment of the relay; means responsive to depletion of supervisory line pressure for developing pressure in the control line; and means responsive to the development of control line pressure to a value equal to the pressure limitation imposed by said pressure limiting means to restore communication between said control line and the abutment of said relay.

10. In a iluid pressure brake system, the combination of a normally charged supervisory line; a local reservoir charged therefrom; means preventing back ilow from the reservoir to the supervisory line; a normally vented control line; a brake cylinder; a relay valve comprising an actuating abutment normally subject to control line pressure and valve means operable thereby to admit pressure iluid from said reservoir to the brake cylinder` and to exhaust said brake cylinder to control the application of the brakes; means responsive to the depletion of supervisory line pressure for interrupting the communication between said control line and the abutment of said relay valve and for subjecting said abutment to pressure fluid; pressure limiting means for limiting the pressure so developed upon the abutment of the relay; means responsive to depletion of supervisory line pressure for developing a pressure in the control line; means responsive to the rate of deceleration produced by a brake application for modulating the pressure in the control line; and means responsive to the development of control line pressure to a value equal to the pressure limitation imposed by said pressure limiting means and serving to restore communication between said control line and the relay abutment.

11. In a lluid pressure brake system, the combination of a normally charged supervisory line; a brake cylinder; a control line; a relay valve normally responsive to control line pressure and functioning alternatively to deliver air derived from the supervisory line to the brake cylinder and to exhaust the brake cylinder; means responsive to reduction of supervisory line pressure and serving to actuate said relay valve to produce a brake application; pressure limiting means for limiting the intensity of an application so produced; and means responsive to control line pressure when supervisory line pressure is so reduced for subjecting said relay valve selectively to control by said pressure limiting means or by pressure in said control line.

12. In a luid pressure brake system, the combination of a normally charged supervisory line; a brake cylinder; a control line; a relay valve normally responsive to control line pressure and functioning alternatively to deliver air derived from the supervisory line to the brake cylinder and to exhaust the brake cylinder; means responsive to reduction of supervisory line pressure and serving to actuate said relay valve to produce a brake application; pressure limiting means for limiting the intensity of an application so produced; means responsive to control line pressure when supervisory line pressure is so reduced for subjecting said relay valve selectively to control by said pressure limiting means or by pressure in said control line; and means responsive to the rate of deceleration produced by a brake application and serving to modulate control line pressure.

13. In a fluid pressure brake system, the combination of a relay valve; a control line and a supervisory line associated therewith, said supervisory line being normallycharged and serving to supply pressure fluid under control of the relay valve, and said control line normally controlling the operation of the relay valve; means responsive to venting of the supervisory line for isolating said relay valve from said control line and causing the relay valve to apply the brakes; and means responsive to development of pressure in the control line for reestablishing the controlling communication thereof with the relay valve.

14. In a fluid pressure brake system, the combination of a relay valve comprising admission and exhaust valve means arranged to control a brake application and a movable abutment connected to actuate said valve means; a control line to whose pressure said abutment is normally subject; a normally charged supervisory line; a local reservoir fed thereby and arranged to supply pressure fluid to said relay valve for brake applications; means responsive to venting of the supervisory line to isolate said abutment from said control line and connect it with said reservoir; pressure limiting means for limiting the pressure developed on said abutment by flow from said reservoir; and means responsive to control line pressure and serving when control line pressure attains the value established by said limiting means, to isolate said abutment from said reservoir and place it in communication with said control line.

15. In a fluid pressure brake system, the combination of a relay valve comprising admission and exhaust valve means arranged to control a brake application, and a movable abutment connected to actuate said valve means; a control line to whose pressure said abutment is normally subject; a normally charged supervisory line; a local reservoir fed thereby and arranged to supply pressure iluid to said relay valve for brake applications; means responsive to venting of the supervisory line to isolate said abutment from said control line and connect it with said reservoir; pressure limiting means for limiting the pressure developed on said abutment by ilow from said reservoir; means responsive to control line pressure and serving when control line pressure attains the value established by said limiting means, to isolate said abutment from said reservoir and place it in communication with said control line; and means responsive to the rate of deceleration produced by a brake application and serving to modulate control line pressure.

16. In a iluid pressure brake system, the combination of a relay valve comprising admission and exhaust valve means arranged to control a brake application, and a movable abutment connected to actuate said valve means; a control line to whose pressure said abutment is normally subject; a normally charged supervisory line; a local reservoir fed thereby and arranged to supply pressure uid to said relay valve for brake applications; means responsive to venting of the supervisory line to isolate said abutment from said control line and connect it with said reservoir; pressure limiting means for limiting the pressure developed on said abutment by iiow from said reservoir; means responsive to control line pressure and serving when control line pressure attains the value established -by said limiting means, to isolate said abutment from said reservoir and place it in communication with said .control line; means responsive to the rate of deceleration produced by a brake application and serving to modulate control line pressure; automatic means for venting said supervisory line; and manually operable means for supplying pressure fluid to said control line under the control of the means responsive to .the deceleration rate. 17. In a fluid pressure brake system, the combination of a normally charged supervisory line; a normally vented control line; means responsive to depletion of supervisory line pressure for developing pressure in the control line; a reservoir charged from the supervisory line; means for preventing back ilow from said reservoir to the supervisory line; a brake cylinder; a relay comprising a pressure actuated abutment and valve means actuated thereby to establish a related pressure in said brake cylinder; a change-over valve, shiftable between a` normal position in which it subjects said abutment to control line pressure, and an abnormal position in which it .admits pressure fluid against said abutment;

pressure limiting means serving to limit the pressure so developed on said abutment; means biasing said change-over valve toward said abnormal position; means responsive to supervisory line pressure and serving when said pressure is above a critical value to hold said change-over valve in normal position; and means responsive to the development of a definite Ypressure in the control line when supervisory line pressure is below said critical value, for holding said change-over valve in said normal position.

18. In a uid pressure brake system, the combination of a normally charged `supervisory line; a normally vented control line; means responsive to depletion of supervisory line pressure for" developing pressure in the .control line; a reservoir charged from the supervisory line; means for preventing back flow from said reservoir to `the supervisory'line; a brake cylinder; a relay comprising a pressure actuated abutment and valve means actuated thereby to establish` a related pressure in said brake cylinder; a change-over valve, .shiftable between a normal position in which it subjects said abutment to control line pressure, and .an abnormal position in which it admits pressure iluid .against said abutment; pressure limiting means serving to limit the pressure so developed; means biasing said changeover valve toward said abnormal position; means responsive to supervisory line pressure and serving when said pressure is above a critical value to hold said change-over valve in normal position; timing means for delaying motion of said changeover valve when the supervisory line is vented; and means responsive to the development of a definite pressure in the control line when supervisory line pressure is bel-ow said critical value, for holding said change-over valve in said normal position.

19. In a uid pressure brake system, the combination of a normally charged supervisory line; a normally vented control line; means responsive to depletion of supervisory line pressure for developing pressure in the control line; a reservoir charged from the supervisoryline; means for preventing back ilow from said reservoir to the supervisory line; a brake cylinder; a relay comprising a pressure actuated abutment and valve means actuated thereby to establish a related pressure in said brake cylinder; a change-over valve, shiftable between a normal position in which it subjects said .abutment to control line pressure, and an abnormal position in which it admits vpressure fluid against said abutment; means biasing said change-over valve toward said abnormal position; `means responsive to supervisory line pressure and serving when said pressure is above a chosen value to hold said changeover valve in normal position; and means responsive to the development -.of a denite pressure in the .control line when supervisory line pressure is below said chosen value, for holding said changeover valve in said normal position.

20. In a fluid pressure brake system, the combination of a normally charged supervisory line a normally vented control line; means. responsive to depletion of supervisory line pressure for developing pressure in the control line; a reservoir charged from the supervisory line; means for preventing back flow from said reservoir .to the supervisory line; a brake cylinder; `a relay comprising .a pressure actuated abutment and valve `means actuated thereby to `establish a related pressure in said brake cylinder; a change-over valve, shiftable between a normal position in which it subjects said abutment to control line pressure, and an abnormal position in which it `admits pressure ud ,against said abutment; means biasing said change-over valve toward said abnormal position; means responsive to supervisory line pressure and serving when said pressure is above a chosen value to hold; said change-over valve in normal position; timing means for `delaying ,motion .of ,said change-over valve when the supervisory line is vented; and means responsive to the development of a definite pressure in the control line when supervisory line pressure is below said chosen value., for holding said change-over valve in said normal position.

2l. In a fluid pressure brake system, the combination of a normally charged supervisory line; a normally vented .control line; means responsive to vdepletion of supervisory line pressure for .developing pressure in the .control line; a reservoir charged from the supervisory line; means for preventing back ow from said reservoir to the supervisory line; a .brake cylinder; a relay comprising ia pressure actuated .abutment and valve means actuated thereby to establish a related pressure in said brake cylinder; a change-over Valve, shiftable between a normal position in which 4it subjects said abutment to ,control line pressure, and an abnormal position in which it admits pressure fluid against said abutment; pressure limiting means serving to limit the pressure so developed; means biasing said changeover valve toward said abnormal position; means responsive to supervisory line pressure and serving when said pressure is above a chosen value to hold said change-over valve in normal position; and means responsive to pressure in the control line and serving when said pressure attains a value equal to the pressure established by said pressure limiting valve to ensure that the change-over valve is held in normal position independently of the action of supervisory line pressure.

22. The combination of a normally vented control line; a normally charged supervisory line; a reservoir connected with the supervisory line; means preventing back flow from said reservoir to the supervisory line; a brake cylinder; a relay valve having an actuating abutment and admission and exhaust valve means actuated thereby to control brake cylinder pressure; and means responsive to the state of charge of the system, and serving when the latter is below a critical value, to admit pressure fluid from the reservoir against said abutment to cause a brake application.

23. The combination of claim 22, in which the means responsive to the state of charge comprises connected differential diaphragms subject in relatively opposite directions to supervisory line pressure, one of said diaphragms being also subject to control line pressure acting in opposition to supervisory line pressure, and biasing means acting on said diaphragms.

24. The combination of claim 22, in which the means responsive to the state of charge comprises connected diiferential diaphragms both subject in relatively opposite directions to supervisory line pressure, the smaller of said diaphragms being subject to control line pressure acting in opposition to supervisory line pressure, a change-over valve actuated by motion of said diaphragms, and biasing means urging said diaphragms and change-over valve in a direction opposed to the direction of action of control line pressure on the smaller diaphragm.

Y 25. In a fluid pressure brake system, the'combination of a relay valve mechanism comprising admission and exhaust valve means for regulating braking pressures, and a movable abutment for actuating the same; a control line normally controlling the pressure on said movable abutment; a normally charged supervisory line; and means responsive to supervisory line pressure and serving when such pressure is below a critical value to isolate said abutment from the control line and subject it to brake applying pressure.

26. In a fluid pressure brake system, the combination of a relay valve mechanism comprising admission and exhaust valve means for regulating braking pressures, and a movable abutment for actuating the same; a. control line normally controlling the pressure on said movable abutment; a normally charged supervisory line; means responsive tov supervisory line pressure and serving when such pressure is below a critical value to isolate said abutment from the control line and subject it to brake applying pressure; pressure limiting means for limiting such brake applying pressure; and means responsive to control line pressure and serving when control line pressure is above the pressure established by said limiting means to restore the connection between the control line and said abutment irrespective of pressure then existing in the supervisory line.

27. In a fluid pressure brake system, the combination of a relay valve comprising admission and exhaust valve means arranged to control a brake application and a movable abutment connected to actuate said valve means; a control line to whose pressure said abutment is normally subject; a normally charged supervisory line; a local reservoir fed thereby and arranged to supply pressure fiuid to said relay valve for brake applications; means responsive to venting of the supervisory line to subject said abutment to a limited pressure; and means effective when the supervisory line is vented and responsive to control line pressure to put the control line into and out of controlling communication with said abutment as control line pressure passes above and below said limited pressure.

28. In a fluid pressure brake system, the combination of a relay valve comprising admission and exhaust valve means arranged to control a brake application and a movable abutment connected to actuate said Valve means; a control line to Whose pressure said abutment is normally subject; a normally charged supervisory line; a local reservoir fed thereby and arranged to supply pressure fluid to said relay valve for brake applications; means responsive to venting of the supervisory line to subject said abutment to a limited pressure; means effective when the supervisory line is vented and responsive to control line pressure to put the control line into and out of controlling communication with said abutment as control line pressure passes above and below said limited pressure; and means responsive to the rate of deceleration produced by a brake application and serving to modulate control line pressure.

29. In a fluid pressure brake system, the combination of a normally charged supervisory line; a local reservoir charged therefrom; means preventing back flow from the reservoir to the supervisory line; a normally vented control line; a brake cylinder; a relay valve comprising an actuating abutment normally subject to control line pressure and valve means operable thereby to admit pressure fluid from said reservoir to the brake cylinder and to exhaust said brake cylinder to control application of the brakes; means responsive to depletion of supervisory line pressure for developing a pressure in the control line; means responsive to the deceleration produced by a brake application for modulating the pressure in the control line; and means responsive to a reduction of supervisory line pressure below a definite value for interrupting communication between said control line and the abutment of said relay valve and for subjecting said abutment to limited fluid pressure and thereafter responsive to rising control line pressure to place the control line in controlling communication with said abutment.

30. The combination of a normally charged supervisory line; a normally uncharged control line; a local reservoir fed from the supervisory line; a local relay connected with said reservoir, and normally responsive to control line pressure to apply and release the brakes; and valve means responsive to supervisory line pressure and adapted to assume control of said local relay, said valve means being adapted to function in response to reduction and restoration of supervisory line pressure respectively to apply and release the brakes by controlling said relay.

3l. In a fluid pressure brake system, the combination of a normally charged supervisory line; a normally charged local reservoir; a normally vented control line; means for supplying pressure uid to the control line to develop pressure therein; a brake cylinder; a relay valve comprising an actuating abutment normally subject to control line pressure and valve means operable thereby to admit pressure fluid from said reservoir to the brake cylinder and to exhaust said brake cylinder to control the application of the brakes; means responsive to the depletion of supervisory line pressure for interrupting communication between said control line and the abutment of said relay valve and for subjecting said abutment to pressure fluid; and means responsive to the rate of deceleration produced by a brake application for cutting off the supply of pressure fluid to the control line and for thereafter venting pressure fluid therefromvto limit the deceleration rate. w w

32. In a uid pressure brake system, the combination of a normally charged supervisory line; a normally charged local reservoir; a normally vented control line; a brake cylinder; arelay valve comprising an actuating abutment normally subject to control line pressure and valve means operable thereby to admit pressure iluid from said reservoir to the brake cylinder and to exhaust said brake cylinder to control the application of the brakes; valve means responsive tothe depletion of supervisory line pressure for interrupting the communication between said control line and the abutment of said relay valve and for subjecting said abutment to pressure fluid; and means responsive to control line pressure and serving above a definite control line pressure to reestablish communication between the control line and the abutment irrespective of the depletion of supervisory line pressure.

33. In a fluid pressure brake system, the combination of a normally charged supervisory line; a normally charged local reservoir; a normally vented control line; a brake cylinder; a relay valve comprising an actuating abutment normally subject to control line pressure vand'valve means operable thereby to admitpressure fluid from said reservoir to the brake cylinder and to exhaust said brake cylinderto control the application ofthe brakes; valve means responsive to the depletion of supervisory line pressure for` interrupting the communication between said control line and the abutment of said relay valve and for subjecting said abutment to. pressure fluid; means responsive to control line pressure and serving above a definite control line pressure to reestablish communication between `the control line and the abutment irrespective of the depletion of supervisory line pressure;` and means responsive to the rate of deceleration produced by a brake application for modulating the pressure in the control line.

34. In a fluid pressure brake system, the combination of a, normally charged supervisory line; a normally charged local reservoir; a normally ventedcontrol line; a brake cylinder; a relayvalve comprising an actuating abutment normally subject to control line pressure and valve means operable thereby to admit pressure fiuid from said reservoir to the brake cylinder and to exhaust said brake cylinder to control the applicatie-n of the brakes; valve means responsive to the depletion of supervisory line pressure for interrupting the communication between said control line and the abutment of said relay valve and for subjecting said abutment to pressure fluid; means responsive to the depletion of supervisory line pressure for establishing pressure in the control line; and means responsive to control line pressure and serving above a denite control line pressure to restore communication between the control line and said abutment.

35. In a fluid pressure brake system, the. combination of a normally charged supervisory line; a normally charged local reservoir; a normally vented control line; a brake cylinder; a relay valve comprising an actuating abutment normally subject to control line pressure and valve means operable thereby to admit pressure fluid from said reservoir to the brake cylinder and to exhaust said brake cylinder to control the application of the brakes; valve means responsive to the depletion of supervisory line pressure for interrupting the communication between said control line and the abutment of said relay valve and for subjecting said abutment to pressure uid; means responsive to the depletion of supervisory ilne pressure for establishing pressure in the control line; means responsive to control line pressure and serving above a definite control line pressure to restore communication between the control line and said abutment; and means responsive to the rate of deceleration produced by a brake application for modulating the pressure in the control line.

i 36. In a fluid pressure brake, in combination, a brake cylinder, a relay valve device operated by an increase in fluid pressure for supplying fluid under pressure to the brake cylinder, a straight air pipe, means for supplying fluid under pressure through said straight air pipe to said relay valve device, a brake pipe, an automatic valve device operated upon a reduction in brake pipe pressure for supplying fluid under pressure to said relay valvedevce, and means associated with said' automatic valve device for cutting 01T communication from the straight air pipe to said relay valve device when pressure in the straight air pipe is lower than the pressure supplied to the relay valve device by said automatic valve device.

37In a uid pressure brake, in combination, a brake cylinder, a relay valve device operated by an increase in iluid pressure for supplying fluid under pressure to the brake cylinder, a straight air pipe, means for supplying iiuid under pressure through said straight air pipe to said relay valve device, a brake pipe, an automatic valve device operated upon a reduction in brake pipe pressure for supplying fluid under pressure to said relay valve device, and means responsive at least in part to pressure in the straight air pipe, for selectively connecting said pipe and said automatic valve device with said relay valve device.

38. In a iluid pressure brake, in combination, a brake cylinder, a brake pipe, a brake controlling valve device operative upon a reduction `in brake pipe pressure for effecting the supply of huid under pressure to the brake cylinder, a straight air pipe, and means operative upon a predetermined flxed pressure in the straight air pipe for establishing a communication through which the brake cylinder pressure is controlled according to the pressure in the straight air pipe.

39. In a brake equipment for vehicles, in combination, a plurality of braking units each including a brake cylinder, means including a brake pipe a reduction in pressure in which controls the supply of uid under pressure to said brake cylinders, means including a straight air pipe for controlling the supply of fluid under pressure to said brake cylinders, and means for automatically effecting a transfer in the control of the supply of fluid under pressure to said brake cylinders from one of said control means to the other of said control means after the brakes have been applied.

40. In a brake equipment for vehicles, in combination, a plurality of braking units each including a brake cylinder, means including a brake controlling valve device operative upon a reduction in brake pipe pressure for controlling the supply of fluid under pressure to said brake cylinders, means including a straight air pipe for controlling the supply of fluid under pressure to said brake cylinders, manually `operable means for effecting a reduction in brake pipe pressure for causing an application of the brakes and for simultaneously eifecting the supply of uid under pressure to said straight air pipe, and means responsive to a predetermined fixed straight air pipe pressure for transferring the control of brake cylinder pressure from that produced by a reduction in said brake pipe pressure to that produced by an increase in straight air pipe pressure.

41. In a brake equipment for vehicles, in combination, a plurality of vbraking units each including a brake cylinder, means including a brake pipe for controlling the supply of fluid under pressure to said brake cylinders, means including a straight air pipe for controlling the supply of fluid under pressure to said brake cylinders, one of said control means being adapted to effect a quick application of the brakes, the other of said control means being adapted to effect a uniform application of said several braking units, and means effective after an application of the brakes in response to the operation of the first named means for transferring the control of the brakes to the second named control means.

42. In a fluid pressure brake, in combination, a brake cylinder, a brake pipe, a straight air pipe, a brake controlling valve device operative upon a reduction in brake pipe pressure for controlling the supply of fluid under pressureto the brake cylinder and upon an increase in fluid pressure for establishing a communication through which the brake cylinder pressure is controlled according to the pressure in the straight air pipe, and means operative upon a predetrmined increase in pressure in the straight air pipe for effecting an increase in -uid pressure in said brake controlling valve device.

43. In a brake equipment for vehicles, in combination, a brake cylinder, means including a brake pipe for controlling the supply of fluid under pressure to said brake cylinder, means including a straight air pipe for controlling the supply of fluid under pressure to said brake cylinder, and means responsive to a predetermined fixed straight air pipe pressure and automatically effective upon the application of the brakes in response to a reduction i'n brake pipe pressure for transferring the control of the brake cylinder pressure to said straight air pipe.

44. In a brake equipment for vehicles, in combination, a plurality of braking units each including a brake cylinder, means including a brake pipe for controlling the supply of iluid under pressure to said brake cylinders, means including a straight air pipe for controlling the supply of fluid under pressure to said brake cylinders, and means automatically effective upon application of the brakes in response to a reduction in brake pipe pressure for transferring the control of the brake cylinder pressure to said straight air pipe.

45. In a brake equipment for vehicles, in combination, a plurality of braking units each including a brake cylinder, means including a brake pipe for controlling the supply of fluid under pressure to said brake cylinders, means including a straight air pipe for controlling the supply of fluid under pressure to said brake cylinders, automatic valve means operative upon a reduction in brake pipe pressure from a running position to an application position for effecting an application of the brakes, and means responsive to a predetermined straight air pipe pressure for returning said automatic valve to its running position for effecting an equalization in pressures within `the several brake cylinders by means of the fluid under pressure supplied to the straight air pipe.

46. In a brake equipment for vehicles, in combination, a plurality of braking units each including a brake cylinder, means including a brake pipe for controlling the supply of fluid under pressure to said brake cylinders, meansincluding a straight air pipe for controlling the supply of fluid under pressure to said brake cylinders, manually operable means for effecting a simultaneous reduction in brake pipe pressure and the supply of iluid under pressure to said straight air pipe, automatic Valve means movable from a running position to an application position responsive to a reduction in brake pipe pressure for effecting an application of the brakes, and means responsive to a predetermined increase in straight air pipe pressure for returning said automatic valve means to its running position for transferring the control of brake cylinder pressure from that produced by a reduction in brake pipe pressure to that produced by an increase in straight air pipe pressure.

47. In a fluid pressure brake, in combination, a brake cylinder, automatic means for controlling the supply of fluid under pressure to and the release of fluid under pressure from said brake cylinder to effect an application and release of the brakes, means independent of the operation of said automatic means to its application position for controlling the supply of iiuid under pressure to and the release of iluid under pressure from said brake cylinder to effect an application and release of the brakes, said rst named means being adapted to effect a quick' application of the brakes, and said second named, means being adapted to effect a quick release of the brakes, and means for effecting a transfer in the control of said brakes from said first named control means to said second named control means after an application of the brakes in response to the operation of said first named control means.

CHARLES A. CAMPBELL. 

